RU2681227C1 - Device for fog dissipation - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to the field of technology that provides exposure to the atmosphere in order to disperse fog on a controlled area of land, and can be used to improve navigation conditions on airfields, highways, seaports, etc. Device contains grounded electrically conductive rods (3) fixed with a certain pitch on frame (2). In the gaps between rods (3) and with a gap relative to their surfaces, discharge electrodes (5) electrically connected to main high-voltage DC power supply (8) are installed. Device is equipped with electrically isolated (6) and with a gap relative to the surfaces of rods (3) on the side of frame opposite to discharge electrodes (5) of frame (3) with additional electrodes (7). Electrodes (7) are electrically connected to additional source of high-voltage DC power supply (9) with a polarity opposite to the polarity of the voltage of main high-voltage power supply (8).EFFECT: improved mist dissipation performance.1 cl, 3 dwg

Description

The invention relates to the field of technology, providing effects on the atmosphere with the aim of dispersing fog in a controlled area. The device can be used to improve navigation conditions at aerodromes, highways, seaports, etc., where to control vehicles it is necessary to fulfill the requirement for visibility range. In addition, the proposed device can be used to provide sports and entertainment events in open areas, as well as for ventilation of air over a large territory, including various quarries.

Known methods of exposure to the atmosphere, based on the use of special substances (reagents). Various vehicles are used to deliver reagents to the protected space: aircraft (see, for example, US patent No. 2815928, IPC A01G 15/00, published December 10, 1957), missiles (see, for example, USSR copyright certificate No. 576839, IPC A01G 15/00), shells (see, for example, Russian Federation Patent No. 2034444, IPC 6 A01G 15/00, published May 10, 1995).

The reagents used are silver iodide (patent No. 2527230, published on 10.24.1950), a mixture of chlorine carbon (patent No. 2160900, published on 06.06.1939), an aqueous solution of calcium chloride with a thickener (patent No. 2934275, published on 26.04. 1960) and others.

The use of these reagents allows you to disperse only supercooled mists. Warm mists with the help of known reagents are not amenable to dispersion.

Known methods for influencing the atmosphere (see, for example, USSR author's certificate No. 71260, IPC A01G 15/00, published July 31, 1948, US patent No. 3456880, IPC A01 G15 / 00 published on July 22, 1969, USSR copyright certificate No. 29675, IPC A01G 15/00, published in 1948, application from Germany No. 4005304, IPC E01H 13/00.). These devices affect the atmosphere using a corona discharge. Corona wires are either raised to the height of the cloud, which determines the high cost of resources and is not always feasible due to weather conditions, or they are blown by an air stream formed by technical means, corona electrodes installed at the surface of the earth.

There is a method of dispersing mists and clouds, which consists in generating electric charges into the atmosphere by connecting corona wires to the high voltage source, fixed through insulators on supports at the surface of the earth (see L. G. Kachurin "Physical fundamentals of impact on atmospheric formations", Hydrometeorological publication, Leningrad, 1978, pp. 287-293).

As follows from the above sources of information, the determining factor in the dispersion of fog in the known method is the space charge acting on the droplets of fog.

A device for dispersing fog according to the patent of the Russian Federation No. 2124288 C1, class. ЕНН 13/00, 12/19/1997, published 01/10/1999, bull. No. 1. The known device comprises wires connected to a current source with a small radius of curvature of the surface, mounted on the insulators of the supports parallel to the conductive grid mounted in a vertical plane passing through the axis of symmetry of the adjacent supports. Known technical solution successfully enough solves the problem of dispersion of the fog. See for example https://www.voutube.com/watch?v=3HnMTvwBOXk.

https://www.youtube.com/watch?v=PGGkdaVStXs. The electrically charged particles generated by the corona discharge are captured by the electric field formed between the corona electrodes and the grounded grid, and move along the directions of electric field lines that close on the surface of the grid wires. Electrically charged particles moving along the lines of force of an electric field entrain electrically neutral air molecules. An ionic wind forms, which is directed from the corona wires to a grounded grid. The speed of the formed ionic wind is determined by the concentration of electrically charged particles generated by the corona discharge and the momentum of the electric field forces acting on them in the direction normal to the surface of the grounded grid. Electrically charged particles in the directions of electric field lines deviate from the normal to the surface of the grounded grid and are deposited on the grounded surfaces of the grid, and neutral particles pass through the gaps between the grounded surfaces to the outside. A wind flow is forming. A cloud of fog passing through the corona discharge region receives an electric charge and is directed by an ionic wind, as well as by an external wind flow, to an earthed grid. Electrically charged droplets of fog move in the directions of the electric field lines, are deposited on the grounded surfaces of the grid and are separated from the wind stream and the wind stream cleaned from fog is sent to the area of the space protected from fog. At the same time, the stability of the corona discharge burning, and, consequently, the efficiency of the device, largely depends on the accuracy of the gap between the corona wires and the grounded grid. In places where the gap is less than the design value, an electrical breakdown occurs, and the entire corona generation system turns off. In places where the gap value is greater than the design value, the intensity of the corona discharge is insufficient for efficient fog dispersion. Providing the required flatness characteristics of the grid surface is a very difficult technical task.

The closest technical solution to the proposed is a device for dispersing fog according to the patent of the Russian Federation 2516988 Ru, C1, IPC A01G 13/00 (2006/01), published on 05.27.2014, bull. No. 15. This device contains a grounded electrically conductive grid mounted on the frame, over which electrically conductive rods are installed with a certain step, along which surfaces, with a gap, corona electrodes connected to the high-voltage power supply are connected, connected to the high-voltage power supply.

The known device provides a guaranteed value of the gap of the discharge gap, which allows you to form a stable corona discharge and ensure the effective operation of the fog dispersion device. However, as shown by the results of experimental studies, the known device can effectively disperse the fog in the direction of its movement. In conditions of calm fog, the known device scatters the fog only to the depth of propagation of the jet of the outgoing wind stream formed by the device, the value of which reaches no more than 2 m / s, which limits the effectiveness of its use.

The aim of the invention is to increase the efficiency of dispersion of the fog.

To achieve the stated goal, a known fog dispersion device comprising grounded conductive rods fixed at a certain step on the frame, in the intervals between which and with a gap relative to their surfaces, corona electrodes are electrically connected to the main high-voltage DC power supply, equipped with electrically isolated and with a gap relative to the surfaces of the grounded conductive rods opposite to the corona electro s side frame additional electrodes electrically connected with an additional source of high voltage direct current power supply with a polarity opposite to the main high-voltage power source.

The technical result in the proposed technical solution is achieved due to changes in the space between the grounded conductive rods of the parameters of the electric field. The electric potential of the additional electrodes is part of the electric field lines that came from the corona electrodes and closed on the grounded conductive rods, pulls them along the normal to the plane of the grounded conductive rods to the surface of the additional electrodes. The number and length of the electric field lines coinciding with the direction of the normal to the plane of the grounded conductive rods increases. Accordingly, the impulse of the electric field forces acting on the electrically charged particles generated by the corona discharge in the direction normal to the plane of the grounded conductive rods increases, their speed increases, which ensures an increase in the speed of the generated wind flow.

In fig. 1.1-1.3 presents a schematic diagram of a device for dispersing fog. The device includes a frame 2 mounted on supports 1, on which grounded conductive rods 3 are mounted with a pitch h. In between the conductive rods 3, corona electrodes 5 are mounted electrically isolated, for example, on electrical insulators 4 with a gap relative to the surfaces of the grounded conductive rods 3 The corona electrodes 5 can be installed both in the plane spaced from the plane of the grounded conductive rods 3 at a distance of δ ₁ and directly in the gap m between grounded conductive rods 3. Grounded conductive rods 3 can be made in the form of round cylinders, as shown in Fig. 1.1-1.3, and in the form of flat surfaces (for example, from pipes of profile rectangular). On the opposite side of the corona electrodes 5 of the side of the frame 2 on insulators 6 with a gap relative to the surfaces of the grounded conductive rods 3, additional electrodes 7 are installed in a plane spaced from the plane of the grounded conductive rods 3 at a distance of δ _2. Additional electrodes 7, as well as grounded conductive rods 3 can be made in the form of round cylinders, as shown in Fig. 1.1-1.3, and in the form of flat surfaces (for example, from pipes of profile rectangular). The corona electrodes 5 are electrically connected to a high-voltage source of electrical power of direct voltage 8. For example, a positive polarity. Additional electrodes 7 are connected to a high voltage DC power supply 9, the polarity of which is opposite to the voltage polarity of the main high voltage power supply 8. In Fig.1.2, the polarity of the main power supply 8 is indicated by the sign (+), the polarity of the additional power supply 9 is indicated by the sign (-).

The proposed device operates as follows.

The device is turned on by applying a high DC voltage to the corona and additional electrodes (5, 7). From the high-voltage power supply 8, a high constant voltage of the same sign is applied to the corona electrodes 5, and a high voltage of opposite polarity from an additional high-voltage power supply 9 is supplied to the additional electrodes 7. In Fig. 1.2, it is conventionally indicated by the signs (+) and (-). When a high voltage is applied to the corona electrodes 5, a powerful electric field is formed between the corona electrodes 5 and the grounded conductive rods 3. The voltage value of the high-voltage power source is selected based on the conditions for the formation of a stable corona discharge on the corona electrode 5 and the resistance of the high-voltage insulators 4. When a corona discharge is generated, electrically charged particles are formed in the discharge gap under the influence of a powerful electric field formed by a set of electric charges localized on corona 5 and an additional 7 electrodes located near grounded conductive rods 3 move along it with lauryl lines that extend to the surfaces of the additional electrodes. In the process of their movement, electrically charged particles collide with electrically neutral air particles and transmit their momentum of movement to them and a wind flow is formed from the corona electrodes 5 in the direction of the grounded electrode rods 3. In contrast to the known technical solution, the formation of the wind flow in the proposed technical solution is not only in the region of the discharge gap between the corona electrodes 5 and the grounded conductive rods 3. But it extends far and its limits, until additional electrodes 7. surfaces lengthens the path of movement of electrically charged particles in an electric field. The time of transmission of a force impulse from electrically charged particles to electrically neutral air particles is increased, which increases the speed of air movement, and, accordingly, the speed of the entire formed air flow increases. The mist droplets contained in the air stream fall into the discharge gap, where the mist droplets acquire the electric charge of the charge sign of the corona electrodes 5. When the air stream passes past the grounded conductive rods 3 and additional electrodes 7 having an electric charge of the opposite sign of the electrically charged mist droplets. Electrically charged mist droplets are deposited by an electric field on their surfaces of grounded conductive rods 3 and additional electrodes 7, and are separated from the wind flow. The air stream cleared of droplets leaves the fog dispersal device and is directed to the protected area, displacing fog from it. Drops of fog collect on the surfaces of the grounded conductive rods 3 and additional electrodes 7, and flow down under the influence of their own weight. If necessary, the drained moisture can be collected in special tanks (not shown in Fig. 1.1-1.3).

A corona discharge is formed between the corona electrodes 5 and the surface of the grounded conductive rods 3. The electric field of the additional electrodes 7 acts on the electric charges formed by the corona electrodes and ensures their movement from the corona electrodes to its surface. The influence of the electric field from the additional electrodes 7 on the parameters of the electric field at the surface of the corona electrodes 7 is negligible. Therefore, schematically, the proposed device from the point of view of forming the air flow can be divided into two electrical circuits.

The first circuit is an electrical circuit that provides the formation of electrically charged particles, electrical charging and deposition of mist droplets on the grounded surface. This electrical circuit is closed by a corona discharge, includes a high-voltage power supply 8 connected to corona electrodes installed with a gap relative to the grounded conductive rods 3.

The second circuit is an electric circuit that ensures the formation of a wind flow by moving electrically charged particles formed by the first circuit from the corona electrodes 5 through the gaps between the grounded conductive rods 3 to the additional electrodes 7. This circuit is closed by electrically charged particles that formed in the corona discharge region and passed past the grounded conductive rods 3 and deposited on the surface of the additional electrodes 7. The circuit includes an additional source power supply 9 connected to additional electrodes 7, and electrically charged particles formed in the corona discharge generation region.

The efficiency of the dispersion of the fog largely depends on the speed of the generated device cleaned from droplets of fog air flow. In the known device for dispersing fog, to increase the speed of the formed air flow, an increase in the intensity of the corona discharge is required, which forces one to work in corona discharge modes on the face of electric breakdown of the discharge gap. Ensuring stable burning of the corona discharge in the current mode, and, therefore, ensuring higher efficiency of the device depends on the accuracy of the gap between the corona wires and the grounded surface, on the uniformity of the parameters of the air in the discharge gaps, the presence of various inhomogeneities on the corona electrodes, etc. In places where the gap is less than the design value, where the electric strength of the air gap is less, where various inhomogeneities are formed on the surfaces of the electric Odes, an electrical breakdown occurs, and the entire corona generation system turns off. If the gap is larger, the intensity of the corona discharge is insufficient to effectively ensure dispersion of the fog. To ensure high uniformity of parameters that determine the stability of the corona discharge in fog dispersion devices operating in open areas and having significant overall dimensions is a very difficult technical task.

The second electric circuit promotes electrically charged particles and generates a high-speed wind flow, which allows for efficient operation of the device without a significant increase in the intensity of corona discharge generation and to achieve its high fog dispersion efficiency in less intense, stable corona discharge modes.

Thus, the proposed device due to new, previously unknown features allows you to divide the process of forming the air flow into two independent components and implement it in two independent devices. The first forms electrically charged particles. The second provides imparting a momentum to the electrically charged particles. Moving electrically charged particles collide with neutral particles of air. They transmit part of their momentum to them, and an air stream is formed. As a result, the proposed device, in conditions of stable corona discharge, allows to form a drop-free air flow with a speed exceeding the speed of the air flow from the known device, which allows to achieve the purpose of the proposed invention.

Claims (1)

A fog dispersal device comprising grounded conductive rods fixed with a certain step on the frame, in the intervals between which and with a gap relative to their surfaces, corona electrodes are electrically connected to the main high-voltage DC power supply, characterized in that it is equipped with electrically isolated and with a gap relative to the surfaces of the grounded conductive rods from the side of the frame opposite from the corona electrodes additional electrodes electrically connected to an additional source of high voltage DC power supply with a polarity opposite to the voltage polarity of the main high voltage power source.

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